活性艳红K-2G与环糊精相互作用的极谱伏安法研究

研究了单偶氮染料活性艳红K-2G的极谱伏安行为。实验表明：在底液为0．1mol／L的NaGl溶液中活性艳红K-2G有一稳定的、灵敏的还原峰,峰电位约为-0．78mV（vs．SEE）。用线性扫描二阶导数极谱法研究了活性艳红K-2G与不同环糊精的相互作用。采用“电流法”测定了包结常数,比较了不同类型环糊精的包结能力,初探了包结点的可能位置,并对其进行了理论分析。     

纳米TiO_2膜修饰电极异相电催化还原马来酸

通过电化学合成前驱体和溶胶 -凝胶法在Ti表面修饰一层纳米TiO2 膜 ,SEM ,XRD测试表明晶型为锐钛矿型 ,晶粒平均尺寸为 2 5nm .采用循环伏安法、循环方波伏安法和电解合成法研究了纳米TiO2 膜电极在硫酸介质中的氧化还原行为以及对马来酸 (maleicacid)还原的电催化活性 .结果表明 ,纳米TiO2 膜电极在阴极扫描时有两对可逆氧化还原峰 ,可逆半波电位Er1/ 2 分别为 -0 .5 3V和 -0 .92V (vs .SCE ,扫描速度 0 .0 5V·s-1) ,对应于TiO2 /Ti2 O3 和TiO2 /Ti(OH) 3 两个氧化还原电对的可逆电极过程 .其中TiO2 /Ti2 O3 电对对马来酸具有异相电催化还原活性 ,纳米TiO2 膜中的TiⅣ/TiⅢ 氧化还原电对作为媒质间接电还原马来酸为丁二酸 (butanediacid) ,反应机理为电化学偶联随后化学催化反应 (EC′)机理 .     

高活性Ti基纳米TiO2膜催化电极的制备

采用“牺牲职极法”恒槽压电解含有0．005mol.L^-1四乙基基溴化铵的醇溶液,加入微量乙醇丙酮作稳定剂,电合成TiO2前驱体钛酸乙酯Ti(EtO)4,经水解、涂膜、煅烧制备Ti基纳米TiO2膜电极（Ti/nano-TiO2)。TEM、SEM、XRD测试表明：TiO2颗粒尺寸在10－35nm`,膜厚达0．5μm主要为锐钛矿晶型,膜为多孔三维网状结构,循环伏安法研究了纳米TiO2膜电极对草酸还原为乙醛酸、硝基苯还原为对氨基苯酚反应的电催化活性,结果发现纳米膜中的Ti( Ⅳ）/Ti（Ⅲ）氧化还原电对起一种中介作用,可使有机物如草酸和硝基苯间电还原,且电极催化活性高,性能稳定 。     

低分子醇的流动注射双安培传感器

基于不可逆电对的双安培检测原理，设计了快速检测低分子醇的流动注射双安培传感器。该传感器由一支表面修饰有氧化铂的铂电极和一支洁净的铂电极构成，通过偶合一支电极上低分子醇的吸附氧化和另一支电极上氧化铂的还原两个不可逆电对，构建了双安培检测体系。在外加电位差为0．00V时，甲醇、乙醇、乙二醇、正丙醇、丙三醇的吸附氧化电流与其浓度分别在0．01－8．00、0．01－8．00、0．01－8．00、0．01－4．00、0．01－4．00mol/L范围内呈线性关系；检出限分别为0．003、0．003、0．001、0．006、0．006mol/L(S/N=2)。该传感器具有结构简单、选择性好、效率高（180样／h)等优点，已成功应用于啤酒中乙醇的直接测定。     

生理条件下对苯二酚的电化学行为及电极产物的色谱鉴定

用循环伏安法研究了对苯二酚在玻碳电极上的电化学行为，从循环伏安图上看出当在0至1．6V电位间连续扫描20次，在0．63V左右可见到一氧化峰电位，其峰电流随扫描次数的增加而减小。说明电极反应为不可逆过程。然而，如改变在-1．4～1.6V电位间扫描，仅数次扫描后即可在Epa=0．25V和Epc=-0．08V处见到一对氧化还原峰电位，说明了此过程为一可逆过程。同时，对电极反应的产物用RHPLC进行研究和鉴定，从色谱图所示结果与电化学法所得结果一致。根据此工作的研究结果对苯二酚在呼吸链中所产生的作用进行了探讨。     

化学修饰电极的研究——Ⅹ.普鲁士蓝修饰电极的表面表征及离子效应

本文通过红外光谱、X射线衍射法的表面表征,证实了电积法牢固接着在Pt电极表面的蓝色电活性膜确实为普鲁士蓝(PB);X射线衍射实验直接测定了PB膜的晶体结构。多种离子效应实验表明PB膜在电化学氧化还原过程中只有阳离子的穿透,与共存阴离子无关;除K~+,NH_4~+,Cs~+外,Na~+离子也可穿透膜。PB膜的电化学氧化还原反应为:PB 还原PB 氧化其中0相似文献   

血红素LB膜的电化学行为

采用循环伏安法研究了血红素与脑磷脂混合Y型LB（Langmuir-Blodgett）膜在玻碳电极上的电化学行为，结果表明血红素LB膜有良好的电化学活性，在0．1mol/L KCl溶液中有一对氧化还原峰（－0．42V／－0．30V）；将血红素LB膜转移到玻碳电极表面得到的血红素LB膜修饰电极（heme LB-GC）对溶液中溶解氧的电化学还原有良好的催化作用，其催化还原过程具有不可逆电荷传递特性。     

金电极表面聚赖氨酸固定微过氧化物酶-11的电化学研究

通过聚赖氨酸修饰将微过氧化物酶-11(MP—11)固定在金电极表面，制备成MP-11修饰电极．修饰在电极表面上的MP-11的血红素活性中心与电极之问可进行直接的电子传递反应，其氧化还原式电位为-0.39V.该修饰电极对氧的还原具有电催化活性．当MP-11与咪唑发生轴向配位反应时，其氧化还原式电位发生负移，此时对氧的还原不再具有电催化活性．     

纳米TiO_2膜修饰电极异相电催化还原马来酸

通过电化学合成前驱体和溶胶-凝胶法在Ti表面修饰一层纳米TiO_2膜，SEM， XRD测试表明晶型为锐钛矿型，晶粒平均尺寸为25 nm。采用循环伏安法、循环方波 伏安法和电解合成法研究了纳米TiO_2膜电极在硫酸介质中的氧化还原行为以及对 马来酸（maleic acid）还原的电催化活性。结果表明，纳米TiO_2膜电极在阴极扫 描时有两对可逆氧化还原峰，可逆半波电位E_(1/2)~r分别为-0.53 V和-0.92 V（ sv. SCE，扫描速度0.05 V·s~(-1)），对应于TiO_2/Ti_2O_3和TiO_2/Ti(OH)_3两 个氧化还原电对的可逆电极过程。其中TiO_2/Ti_2O_3电对对马来酸具有异相电催 化还原活性，纳米TiO_2膜中的Ti~(IV)/Ti~(III)氧化还原电对作为媒质间接电还 原马来酸为丁二酸（butane diacid），反应机理为电化学偶联随后化学催化反应 （EC'）机理。     

Ti表面修饰纳米TiO2膜电极的电催化活性

用电化学合成法在Ti表面修饰一层纳米TiO2膜，TEM和XRD测试表明晶型为锐钛矿型，晶粒平均尺寸为25nm。用循环伏安法，循环方法伏安法和电解合成法研究了纳米TiO2膜电极在硫酸介质中的氧化还原行为以及对硝基苯还原的电催化活性。结果表明，纳米TiO2膜电极具有异相氧化还原催化行为，膜中的Ti(Ⅳ）/Ti（Ⅲ）作为媒质间接电还原硝基苯为对氨基苯酚，收率和电流效率分别达91．6％和95．2％。     

Direct Electrochemistry of Catalase at a Gold Electrode Modified with Single‐Wall Carbon Nanotubes

The direct electrochemistry of catalase (Ct) was accomplished at a gold electrode modified with single‐wall carbon nanotubes (SWNTs). A pair of well‐defined redox peaks was obtained for Ct with the reduction peak potential at ?0.414 V and a peak potential separation of 32 mV at pH 5.9. Both reflectance FT‐IR spectra and the dependence of the reduction peak current on the scan rate revealed that Ct adsorbed onto the SWNT surfaces. The redox wave corresponds to the Fe(III)/Fe(II) redox center of the heme group of the Ct adsorbate. Compared to other types of carbonaceous electrode materials (e.g., graphite and carbon soot), the electron transfer rate of Ct redox reaction was greatly enhanced at the SWNT‐modified electrode. The peak current was found to increase linearly with the Ct concentration in the range of 8×10^?6–8×10^?5 M used for the electrode preparation and the peak potential was shown to be pH dependent. The catalytic activity of Ct adsorbates at the SWNTs appears to be retained, as the addition of H₂O₂ produced a characteristic catalytic redox wave. This work demonstrates that direct electrochemistry of redox‐active biomacromolecules such as metalloenzymes can be improved through the use of carbon nanotubes.     

Surface functionalization with redox active molecule-based imidazolium via click chemistry

In this study, the redox active molecule N-ferrocenylmethyl-N-propargylimidazolium bromide was immobilized onto the surface of an electrode. The surface modification was performed by coupling the electrochemical reduction of the 4-azidophenyldiazonium generated in situ with a copper(I) catalyzed click chemistry reaction. Surface and electrochemical investigations suggest the attachment of a monolayer of redox active molecules containing an ionic liquid framework onto the electrode surface. Furthermore, scanning electrochemical microscopy studies revealed the conductive behavior of the attached ferrocenyl moieties on the ITO surface.     

Molecular electronics at electrode–electrolyte interfaces

Four contemporary examples, all published in recent years, of studies of molecular electronics at electrode–electrolyte interfaces are reviewed in this opinion article. The first illustrative example involves the switching of the redox active molecular wire between redox states, with concomitant changes in molecular conductance. This example illustrates how molecular electronics at electrode–electrolyte interfaces can be used to analyse mechanisms of electron transfer, to distinguish electrolyte effects and to provide details not readily available from ensemble measurements. The second example shows that the fluctuations of molecular conductance of a redox active molecular wire can be followed as a function of electrode potential. This shows how the stochastic kinetics of individual reaction events at electrode–electrolyte interfaces can be followed. The third example demonstrates how electrochemistry can be used to control quantum interference in single molecular wires. The fourth example shows a single-molecule electrochemical transistor concept for well-defined metal cluster containing molecular wires.     

RuO2电极伏安特性

本文用循环伏安法和微分脉冲极谱法研究RuO_2电极的优安特性。结果表明, 在0.2～0.8 V电位区存在两个氧化还原反应; RuOOH<=>RuO_2+H~+e 和 RuO_2+H_2O<=>RuO_3_2H~++2e而不是一个氧化还原反应(RU(Ⅲ)→Ru(Ⅳ)); 且电极的析氧活性中心为氧结构空位, 它的消失导致电极的失活。     

Fabrication, Characterization and Electrocatalysis of an Ordered Carbon Nanotube Electrode

A method for fabrication of ordered carbon nanotube (CNT) film,which was template-synthesized within the highly ordered pores of a commercially available alumina template membrane,modified glassy carbon(CNT/GC) electrode was established.The CNT/GC electrode showed excellent electrocatalytic activity toward dopamine electrochemical reaction without introducing any electrochemically active group into CNT film or activating any electrochemically active group into CNT film or activating the electrode electrochemically.DA undergoes ideal reversible electrochemical reaction on CNT/GC electrode at low scan rate(≤20mV/s) with an excellent reproducibility and stability.The CNT/GC electrode might be used in biosensors because the highly ordered CNT may present a steric effect on more efficient redox reactions of biomolecules.     

Colloidal Supercapattery: Redox Ions in Electrode and Electrolyte

Redox chemistry is the cornerstone of various electrochemical energy conversion and storage systems, associated with ion diffusion process. To actualize both high energy and power density in energy storage devices, both multiple electron transfer reaction and fast ion diffusion occurred in one electrode material are prerequisite. The existence forms of redox ions can lead to different electrochemical thermodynamic and kinetic properties. Here, we introduce novel colloid system, which includes multiple varying ion forms, multi‐interaction and abundant redox active sites. Unlike redox cations in solution and crystal materials, colloid system has specific reactivity‐structure relationship. In the colloidal ionic electrode, the occurrence of multiple‐electron redox reactions and fast ion diffusion leaded to ultrahigh specific capacitance and fast charge rate. The colloidal ionic supercapattery coupled with redox electrolyte provides a new potential technique for the comprehensive use of redox ions including cations and anions in electrode and electrolyte and a guiding design for the development of next‐generation high performance energy storage devices.     

Electrochemical reactivity at redox-molecule-based nanoelectrode ensembles

A model describing electrochemical reactivity at nanoelectrode ensembles consisting of redox-molecule-based active sites immobilized on otherwise passivated electrode surfaces is presented. A mathematical treatment in terms of hemispherical diffusion of redox-active solutes to a layer of independent molecule-based nanoelectrode sites is shown to be equivalent to one in terms of a bimolecular diffusion-limited reaction between a layer of immobilized redox molecules and a reservoir of redox-active solutes. This equivalence derives from the fact that in both cases the mass-transfer problem is essentially that of hemispherical diffusion. The model is further developed to consider rate limitation by both the bimolecular redox reaction between the active-site molecule and redox molecules in solution and the heterogeneous redox reaction between the electrode and the active-site molecule. Analytical expressions are derived for the current–voltage relation corresponding to catalyzed electron transfer at an ensemble of redox-molecule-based nanoelectrode sites, and the expressions are used to interpret preliminary data for ultrasensitive electrochemical detection in flow streams via an electrochemical amplification process that is thought to involve redox mediation by individual analyte molecules adsorbed onto monolayer-coated electrodes.     

Electropreparation of Poly(benzophenone‐4) Film Modified Electrode and Its Electrocatalytic Behavior Towards Dopamine,Ascorbic Acid and Nitrite

The oxidation of benzophenone‐4 (2‐hydroxy‐4‐methoxybenzophenone‐5‐sulfonic acid) at glassy carbon electrode gives rise to stable redox active electropolymerized film during repetitive potential cycling between 0 to 1.3 V (Ag/AgCl). Cyclic voltammogram of poly(benzophenone‐4) film shows a redox couple with well‐defined peaks. The redox response of the modified electrode was found to be depending on the pH of the contacting solution. The peak potentials were shifted to a less positive region with increasing pH and the dependence of the peak potential was found to be 51 mV/pH. The electrocatalytic behavior of poly(benzophenone‐4) film modified electrode towards oxidation of dopamine, ascorbic acid and reduction of nitrite was investigated. The oxidation of dopamine and ascorbic acid occurred at less positive potential on poly(benzophenone‐4) film compared to bare glassy carbon electrode. For dopamine, the overpotential was reduced about 180 mV. Feasibility of utilizing poly(benzophenone‐4) film coated electrode in analytical estimation of dopamine, ascorbic acid and nitrite was also demonstrated.     

Insights into electrocatalytic activity of epitaxial graphene on SiC from cyclic voltammetry and ac impedance spectroscopy

Electrocatalytic activity of graphene grown epitaxially on SiC is studied using cyclic voltammetry and electrochemical impedance spectroscopy. AFM images show step-like topography of SiC-graphene. For ferri-/ferrocyanide redox couple, no voltammetric response is observed at the pristine graphene. Basal planes of graphite are electrochemically inactive as well. After electrochemical oxidation, apparent redox peaks appear at both the graphene and graphite electrode. However, more intensive redox peaks are observed at graphene, where simultaneous redox reaction with the adsorbed and the diffused ferri-/ferrocyanide ions occurs. Electrochemical impedance measurements show that the graphene electrode behaves like an array of microelectrodes. We used the partially blocked electrode model to fit impedance data. Using the fitting parameters, a size of microelectrodes was found to be 23.8?±?2.1 μm and the active surface of graphene was estimated to be 21 %. A value of the standard electron transfer rate constant found for the anodized epitaxial graphene (2.16?±?0.32)?×?10^??3cm???s^??1) is by one order of magnitude lower than the standard rate constant estimated for the anodized graphite basal planes (～5?×?10^??2cm???s^??1). Electrochemical reduction causes total disappearance of electrochemical responses at the graphene electrode, whereas only slight decrease of the peak currents is observed at the reduced graphene. Such behavior proves that different activation mechanisms occur at the graphene and graphite electrodes.     

A New Redox Reaction of Ascorbic Acid at Platinum Electrodes

A pair of new redox peaks of ascorbic acid at a platinum electrode was found and studied in detailed by spectroelectrochemistry and electrochemistry technologies. This is a quasi‐reversible redox reaction with a one‐electron transfer process. The intermediate of tertiary carbon free radical exists in this process. The appearance reaction rate constant and the diffusion coefficient were investigated. A possible reaction mechanism has been proposed.